JP5222672B2 - Crystallization reactor and crystallization reaction method - Google Patents

Description

  The present invention relates to a crystallization reaction apparatus and a crystallization reaction method for treating and recovering fluorine from raw fluorine-containing water such as a semiconductor factory as calcium fluoride.

  Conventionally, in order to treat fluorine-containing raw water containing fluorine, a coagulation precipitation method in which a calcium agent and a coagulant are added is generally used, and slaked lime is often used as the calcium agent. However, since the calcium fluoride sludge produced by this method has low purity, it is difficult to recover and reuse.

As a method for recovering calcium fluoride by adding a calcium agent to the fluorine-containing raw water, the fluorine-containing raw water and the calcium agent are injected into a crystallization reaction tank filled with a seed crystal, and calcium fluoride is applied to the surface of the seed crystal. A crystallization method or the like for precipitating calcium fluoride to obtain calcium fluoride crystals has been proposed.
2HF + CaCl ₂ → CaF ₂ ↓ + 2HCl

  When the fluorine content of the fluorine-containing raw water is low, it is crystallized at a pH of 3 to 11 with a fluidized bed type crystallizer (fluidized bed type, see FIG. 10, Patent Document 1). The present inventors have proposed that crystallization is performed at a pH of 2 to 3 in a crystallization reaction tank equipped with a tube and a stirrer (stirring crystallization apparatus, see FIG. 11 and Patent Document 2).

  In the above prior art, calcium chloride is used as a calcium agent. In addition to the above-mentioned proposal by the inventors, for example, Patent Document 3 recommends calcium chloride as a calcium agent. In Patent Document 4 targeting high-concentration hydrofluoric acid, calcium chloride is used as a calcium agent.

  The reason why slaked lime is not used as a calcium agent in the crystallization method is largely due to the difficulty in handling slaked lime. Since slaked lime has a low solubility in water (25 ° C.) of 0.149 g / 100 g, it is generally used as a powder or slurry. In the crystallization method, since a liquid is easier to use from the viewpoint of controlling the amount of calcium agent injected, a calcium chloride solution is generally used.

  On the other hand, slaked lime is very cheap compared to calcium chloride and has a merit that it can be easily diverted because there is a supply facility in the semiconductor factory. When slaked lime is used in the crystallization method, there is a method in which slaked lime is dissolved in an acid to form calcium chloride and then injected into a crystallization reaction tank (for example, Patent Documents 4 and 5).

  As a method of using slaked lime without dissolving it, Patent Document 6 proposes a method of adding slaked lime to the lower part of the fluidized bed or the treated water circulation line using a fluidized bed type crystallizer.

JP 2003-225680 A Japanese Patent Application No. 2006-238862 US Pat. No. 5,106,509 JP 2005-206405 A JP 2003-225502 A Japanese Patent No. 1527096

  However, the methods of Patent Documents 4 and 5 require the same amount of acid as a chemical equivalent with respect to slaked lime, and the corresponding cost is required. In addition, the reaction between hydrofluoric acid and calcium chloride generates hydrochloric acid, which lowers the pH, so it is necessary to add an alkali, and the cost is further required. Due to the cost of these acids and alkalis, the reduction in running cost is not so great compared to the case of using a commercially available calcium chloride solution.

  Moreover, when the present inventors actually examined the method of patent document 6, the process was not stabilized and the problem that the fluorine concentration of treated water became high occurred. The reason for this is thought to be that fine calcium fluoride was generated and flowed out of the system in a large amount due to a rapid reaction between undissolved slaked lime and fluorine.

  The present invention is a crystallization reaction apparatus and a crystallization reaction method capable of reducing the fluorine concentration of treated water at a low cost in the treatment of raw fluorine-containing water.

  The present invention is a crystallization reaction apparatus for generating calcium fluoride crystals by adding slaked lime to raw water containing fluorine, comprising a stirring means having a stirring blade, and adding the slaked lime to the raw water to fluorinate It is a crystallization reaction apparatus having a crystallization reaction tank for generating calcium crystals, slaked lime addition means for adding the slaked lime in the vicinity of the stirring blade, and acid addition means for adding an acid.

  In the crystallization reaction apparatus, the acid addition means preferably injects the acid into the vicinity of the stirring blade.

As a reference example, in the crystallization reactor, the acid addition means, the slaked lime before being added to the crystallization reaction tank, you adding the acid.

As a reference example, in the crystallization reactor, the acid addition means, the raw water prior to addition to the crystallization reaction tank, you adding the acid.

As a reference example, in the crystallization reactor, the acid added in a predetermined amount to the raw water, that controls the injection amount of the slaked lime based on pH of the crystallization reaction tank.

  Moreover, in the said crystallization reaction apparatus, it is preferable that the pH of the said crystallization reaction tank is the range of 0.8-3.

  Further, the present invention is a crystallization reaction method for generating calcium fluoride crystals by adding slaked lime to raw water containing fluorine, and stirring the slaked lime in the raw water in the vicinity of the stirring blades while stirring with a stirring blade A crystallization reaction method including a crystallization reaction step of adding calcium to form calcium fluoride crystals and an acid addition step of adding an acid.

  In the crystallization reaction method, it is preferable that the acid is injected in the vicinity of the stirring blade in the acid addition step.

As a reference example, in the crystallization reaction method, in the acid addition step, the slaked lime prior to the addition in the crystallization reaction step, add the acid.

As a reference example, in the crystallization reaction method, in the acid addition step, the raw water prior to the addition in the crystallization reaction step, add the acid.

As a reference example, in the crystallization reaction method, the acid is added in a predetermined amount to the raw water, that controls the injection amount of the slaked lime based on pH in the crystallization reaction step.

  Moreover, in the said crystallization reaction method, it is preferable that pH in the said crystallization reaction process is the range of 0.8-3.

Further, the reference example is a crystallization reaction apparatus for generating calcium fluoride crystals by adding a calcium agent to raw water containing fluorine, comprising stirring means having a stirring blade, and adding the calcium agent to the raw water A crystallization reaction tank for generating calcium fluoride crystals, raw water addition means for adding the raw water to the crystallization reaction tank, and calcium agent addition means for adding the calcium agent to the crystallization reaction tank And an acid addition means for adding an acid to at least one of the raw water and the calcium agent before being added to the crystallization reaction tank and lowering the pH of at least one of the raw water and the calcium agent. When the pH of at least one of the raw water and the calcium agent before being added to the crystallization reaction tank is 4 or more, the acid addition means has a pH of less than 4. The acid is added to.

As a reference example, in the crystallization reactor, the case of adding an acid to the raw water prior to addition to the crystallization reaction tank, the raw water addition means, you added the raw water in the vicinity of the stirring blade.

As a reference example, in the crystallization reactor, when adding an acid before the calcium agent to be added to the crystallization reaction tank, said calcium addition unit, you added the calcium agent in the vicinity of the stirring blade.

As a reference example, in the crystallization reaction apparatus, when an acid is added to the raw water before being added to the crystallization reaction tank, the acid addition means is added to the raw water based on the pH of the crystallization reaction tank. that controls the amount of the acid added.

As a reference example, in the crystallization reaction apparatus, when an acid is added to the calcium agent before being added to the crystallization reaction tank, the acid addition means is based on the pH of the crystallization reaction tank. that controls the amount of acid added.

The reference example is a crystallization reaction method in which calcium fluoride is added to raw water containing fluorine to produce calcium fluoride crystals, and the calcium agent is added to the raw water while stirring with a stirring blade. An acid is added to at least one of the crystallization reaction step of generating crystals of calcium fluoride, the raw water before adding the calcium agent and the calcium agent before adding to the raw water, and at least of the raw water and the calcium agent An acid addition step of lowering any one of the pHs, and in the acid addition step, at least one of the raw water before adding the calcium agent and the calcium agent before adding to the raw water has a pH of 4 or more In this case, an acid is added so that the pH is less than 4.

  In the present invention, in a crystallization reaction apparatus and a crystallization reaction method in which calcium fluoride crystals are formed by adding slaked lime to raw water containing fluorine, slaked lime is added to the raw water while adding acid and stirring with a stirring blade. By adding calcium fluoride crystals in the vicinity of the stirring blade, the fluorine concentration of the treated water can be reduced at a low cost.

  Embodiments of the present invention will be described below. This embodiment is an example for carrying out the present invention, and the present invention is not limited to this embodiment.

  An outline of an example of a crystallization reaction apparatus according to an embodiment of the present invention is shown in FIG. The crystallization reaction apparatus 1 in FIG. 1 includes a raw water storage tank 10 and a crystallization reaction tank 12.

  In the crystallization reaction apparatus 1 of FIG. 1, a raw water addition pipe 32 from the raw water storage tank 10 is connected to the crystallization reaction tank 12 via a pump 18 that is a raw water addition means, and a slaked lime addition pipe 28 is added. It is connected via a pump 14 that is a means, and an acid addition pipe 30 is connected via a pump 16 that is an acid addition means. A treated water discharge pipe 34 is connected to the outlet of the crystallization reaction tank 12. The crystallization reaction tank 12 is provided with a stirring device 20 that is a stirring means including a motor and a stirring blade 22 that stirs the fluid in the crystallization reaction tank 12, and a pH meter 24 that is a pH measurement means. 26. The stirring blade 22 of the stirring device 20 is rotated by the rotational force generated by the motor transmitted through the stirring shaft. The raw water storage tank 10 may be provided with a stirring device.

  The operation of the crystallization reaction method and the crystallization reaction apparatus 1 according to this embodiment will be described.

  Fluorine-containing raw water containing fluorine (hereinafter sometimes simply referred to as “raw water”) is added from the raw water storage tank 10 to the crystallization reaction tank 12 through the raw water addition pipe 32 by the pump 18. Next, the slaked lime slurry containing the slaked lime which is a calcium agent is added to the crystallization reaction tank 12 through the slaked lime addition piping 28 with the pump 14 (slaked lime addition process). Further, acid is added to the vicinity of the stirring blade 22 of the crystallization reaction tank 12 through the acid addition pipe 30 by the pump 16 (acid addition step). In the crystallization reaction tank 12, the fluorine contained in the raw water reacts with slaked lime to produce calcium fluoride crystals (crystallization reaction step). The crystallization reaction liquid is stirred by the stirring device 20. The amount of acid added may be adjusted by controlling the pump 16 based on the pH of the crystallization reaction tank 12 measured by the pH meter 24. The treated water with reduced fluorine generated by the crystallization reaction in the crystallization reaction tank 12 is discharged to the outside of the crystallization reaction tank 12 through the treated water discharge pipe 34.

  In the present embodiment, the slaked lime slurry is added to the crystallization reaction tank 12 in the vicinity of the stirring blade 22. On the other hand, the addition of the raw water to the crystallization reaction tank 12 and the addition of the acid to the crystallization reaction tank 12 can take any form as long as the raw water or the acid can be added to the crystallization reaction tank 12. The addition pipe 32 and the acid addition pipe 30 can be connected to any part of the crystallization reaction tank 12. In the case of a stirring crystallization reaction tank as shown in FIG. 1, the raw water addition pipe 32 is preferably connected to the upper part of the crystallization reaction tank 10 from the viewpoint of separation of precipitates and treated water. Moreover, in FIG. 1, although the raw | natural water addition piping 32, the slaked lime addition piping 28, and the acid addition piping 30 are each one, it is not limited to this, These may be provided with two or more.

  In this method, the fluorine concentration of the treated water can be reduced by adding slaked lime slurry in the vicinity of the stirring blade 22. The reason for this is that by adding slaked lime slurry in the vicinity of the stirring blade 22, the slaked lime slurry diffuses instantaneously, so that the slaked lime becomes easy to melt, suppresses the rapid reaction between the undissolved slaked lime and fluorine, It is thought that there is an effect that can reduce the production of calcium fluoride.

  In this embodiment, the pH of the crystallization reaction solution in the crystallization reaction tank 12 is preferably in the range of 0.8 to 3, more preferably in the range of 1 to 1.5. By adding an acid and operating the pH of the crystallization reaction tank 12 in the range of 0.8 to 3, the fluorine concentration of the treated water can be significantly reduced. The reason for this is that, in addition to adding slaked lime slurry in the vicinity of the stirring blade 22, slaked lime is more easily dissolved by operating at a low pH of 0.8-3, It is considered that there is an effect of further suppressing the rapid reaction. If the pH of the crystallization reaction solution in the crystallization reaction tank 12 is less than 0.8, the proportion of fluorine in the raw water that does not become calcium fluoride increases, and a large amount of soluble fluorine remains in the treated water. The recovery rate of fluorine may decrease, and if it exceeds 3, slaked lime becomes difficult to dissolve, and fine calcium fluoride may be generated due to a rapid reaction between undissolved slaked lime and fluorine. .

  In addition, in this method, compared with the case where slaked lime is dissolved in an acid to form calcium chloride and then added, the acid consumption can be suppressed to about 1 to 30%. This is presumably because the amount of acid required to dissolve slaked lime is reduced by simultaneously exhibiting the effects of instantaneous diffusion by stirring and dissolution by acid. Moreover, since slaked lime acts also as an alkali, it is not necessary to add alkalis, such as sodium hydroxide, and the cost of an alkali can also be suppressed.

  The pH at the time of precipitation of calcium fluoride is determined by measuring the pH of the reaction field in the crystallization reaction tank 12 using pH measuring means such as a pH meter 24, and in accordance with the measured pH, the acid is put into the tank. By adding, pH can be controlled. The pH meter 24 may be installed in any part of the crystallization reaction tank 12 as long as it can monitor the pH of the reaction field of the calcium fluoride precipitation reaction. There is no particular limitation on the vicinity of the treated water outlet.

  In this specification, “near” the stirring blade 22 means a region where the crystallization reaction liquid in the crystallization reaction tank 12 can quickly diffuse by the stirring flow of the stirring blade 22. For example, the injection point of slaked lime slurry is preferably provided in a region where the stirring flow rate by the stirring blade 22 is large. In particular, the height of the slaked lime slurry injection point in the direction of the rotation axis of the stirring blade 22 is preferably a distance within two times the rotation radius of the stirring blade 22 from the rotation center of the stirring blade 22. In addition, the position of the stirring blade 22 in the direction of the rotation diameter is preferably a distance within twice the rotation radius of the stirring blade 22 from the rotation center of the stirring blade 22. Further, it is preferable that the center is provided in a spherical region whose center is the rotation center of the stirring blade 22 and whose radius is twice the rotation radius of the stirring blade 22. As a result, slaked lime is immediately diffused when injected into the crystallization reaction tank 12, and its concentration quickly decreases. For this reason, slaked lime becomes easy to melt | dissolve, the rapid reaction of the undissolved slaked lime and fluorine can be suppressed, and the production | generation of fine calcium fluoride can be reduced. Further, the formed calcium fluoride is less likely to be directly deposited in the liquid, and the fluorine in the liquid can be taken in carefully as crystals of a hardly soluble salt (calcium fluoride) on the granular seed crystal. Therefore, the amount of fine calcium fluoride mixed in the treated water can be extremely reduced, and the hardly soluble salt particles having a large particle diameter can be stably obtained, and the fluorine recovery rate can be greatly improved.

  The addition position (injection point) of the acid is not particularly limited, and is added to the crystallization reaction liquid in the crystallization reaction tank 12, slaked lime before being added to the crystallization reaction tank 12, and the crystallization reaction tank 12. What is necessary is just to provide so that it may add to at least 1 among the previous fluorine-containing raw | natural waters. For example, as shown in FIG. 1, it can be provided in a region that can quickly diffuse into the crystallization reaction tank 12 by the stirring flow by the stirring blade 22, that is, in the “near” of the stirring blade 22. If the acid is quickly diffused after the injection, the slaked lime is easily dissolved, and the direct generation of hardly soluble salt fine particles that do not depend on the crystallization reaction can be suppressed. Therefore, the fluorine recovery rate can be further improved by discharging the acid to a region where the stirring flow rate is high.

  Further, as shown in FIG. 3, the acid addition pipe 30 may be connected to the slaked lime addition pipe 28 to add the acid to the slaked lime slurry before being added to the crystallization reaction tank 12, or as shown in FIG. In addition, the acid addition pipe 30 may be connected to the raw water storage tank 10 to add acid to the fluorine-containing raw water before being added to the crystallization reaction tank 12. Of these, it is preferable to inject acid into the vicinity of the stirring blade 22 as shown in FIG.

  When adding an acid to the fluorine-containing raw water as shown in FIG. 4, an acid is added to the fluorine-containing raw water in a predetermined amount, and the pump 14 is controlled based on the pH of the crystallization reaction tank 12 measured by the pH meter 24. The pH of the crystallization reaction tank 12 may be controlled by adjusting the amount of slaked lime slurry added. Moreover, the pH meter 36 may be installed in the raw water storage tank 10 to measure the pH of the fluorine-containing raw water.

  In the present embodiment, as shown in FIGS. 1 and 2, it is preferable to install a draft tube 26 below the water surface of the crystallization reaction tank 12 so that the stirring blade 22 of the stirring device 20 is positioned in the cylinder. At this time, the stirring blade 22 preferably forms a downward flow. When the draft tube 26 is installed in this manner, a downward flow is generated toward the lower portion of the tube, and a zone having a relatively large diffusion flow rate is formed. For this reason, raw water, slaked lime, etc. can be diffused more quickly, and it is possible to suppress as much as possible that the regions where the concentrations of raw water and slaked lime are locally concentrated contact each other and direct generation of sparingly soluble salt particles occurs. It becomes.

  Moreover, when the draft tube 26 and the stirring blade 22 are installed as described above, an upward flow zone with a gentle flow is formed on the outer periphery of the tube. In this zone, the particles are classified and the small particles rise along the outer surface of the tube and re-enter the tube from the upper end of the tube and descend.Then, near the injection point of raw water, slaked lime, etc. Recirculate to the agitation zone. These small-sized crystals serve as nuclei to promote the crystallization reaction. For this reason, it becomes possible to stably form crystals of a hardly soluble salt having a large particle size, and the recovery rate of fluorine can be improved.

  Further, the crystal having a larger particle size due to the progress of the crystallization reaction does not rise due to the upward flow at the outer periphery of the tube, sinks down and does not enter the draft tube 26 again. It can be prevented from being destroyed by the collision with the wing 22. Such an advantage also contributes to stably obtaining crystals of a hardly soluble salt having a large particle size, which in turn can contribute to an improvement in the recovery rate of fluorine.

  In order to form a zone with a relatively large stirring flow velocity at the lower part of the tube and to form an upward flow stably on the outer periphery of the tube, the stirring blade 22 must be located somewhere in the lower half of the tube in the tube. preferable. More preferably, a position slightly above the lower end of the tube is good. With such an arrangement, a zone with a high stirring flow rate is formed like a vortex near the lower end of the tube, and an upward flow is stably formed along the outer periphery of the tube. Therefore, diffusion of raw water, slaked lime, etc. and particle classification can be effectively advanced.

  When the draft tube 26 is provided, the raw water, slaked lime, and the acid injection point are arranged in the cylinder of the draft tube 26 in order to quickly and effectively diffuse them on the downflow in the draft tube 26. Is preferred. A more preferable position is in the cylinder of the draft tube 26 and above the stirring blade 22.

  The fluorine-containing raw water in the present embodiment may be raw water of any origin as long as it contains fluorine removed by crystallization treatment, for example, electronic industries including semiconductor-related industries, power plants, aluminum Examples include raw water discharged from industry and the like, but are not limited thereto.

Fluorine serving as a crystallization target substance can be present in the raw water in any state as long as it is crystallized by a crystallization reaction. From the viewpoint that it is dissolved in the raw water, the crystallization target substance is preferably in an ionized state. Examples of the state in which the substance to be crystallized is ionized include, but are not limited to, those in which atoms such as F ⁻ are ionized and those in which a compound containing fluorine is ionized.

  Raw water containing fluorine is also discharged from the aluminum electrolytic refining process, steelmaking process, etc., but in particular, it is discharged in large quantities at semiconductor factories. Concentrated hydrofluoric acid is used for cleaning a semiconductor silicon wafer, etc., and discharged as a concentrated hydrofluoric acid waste liquid with a fluorine content of the order of%. At this time, ammonia, hydrogen peroxide, phosphoric acid, and the like are also used as cleaning agents, and thus may become wastewater containing them. In addition, a large amount of water is used for cleaning hydrofluoric acid remaining on the semiconductor silicon wafer, cleaning HF contained in the gas after decomposition of perfluoro compounds (PFCs), etc., and is also discharged as dilute fluorine-containing raw water. . This method can be particularly suitably applied to remove fluorine from raw water containing hydrofluoric acid (hydrogen fluoride).

  The amount of fluorine contained in the raw water is not particularly limited, but is, for example, in the range of 5000 mg / L to 100,000 mg / L, particularly in the range of 5000 mg / L to 20000 mg / L.

  In this embodiment, slaked lime is used as a crystallizing agent, but the form of adding slaked lime may be in a powder state or a slurry state. The preferable aspect of addition of slaked lime is an aspect added as slaked lime slurry.

  In this specification, “slaked lime slurry” refers to a slurry formed by adding water or an aqueous solution to dry solids of slaked lime, and the water used is any source such as distilled water, purified water, tap water, etc. As the aqueous solution, an aqueous solution obtained by adding an arbitrary compound such as an acid, an alkali, or a salt thereof to the water can be used. In addition, “dry slaked lime solid” in the present specification indicates a concept for the slaked lime slurry, and may be any solid, such as powder, granule, or lump, that does not form a slurry, It does not mean the anhydride.

  As the slaked lime, any grade of slaked lime can be used and is not particularly limited. The density | concentration of slaked lime slurry is not specifically limited, The range of 1 to 20 weight% generally used may be sufficient.

  The amount of calcium injection is preferably 0.8 to 2 times and 1 to 2 times that of fluorine as the chemical equivalent, but more preferably 1 to 1.2 times. If the chemical equivalent of calcium is more than twice the chemical equivalent of fluorine in the raw water, calcium fluoride does not precipitate on the seed crystal and is easily formed as fine particles, and calcium fluoride may be mixed in the treated water. If it is less than 8 times, the proportion of fluorine in the raw water that does not become calcium fluoride increases, and fluorine may be mixed into the treated water.

  The acid to be added is not particularly limited, but is preferably any acid that does not contain a component that forms a sparingly soluble salt with calcium. Examples thereof include hydrochloric acid and sulfuric acid, and hydrochloric acid is preferred.

  In this embodiment, before adding raw water and slaked lime to the crystallization reaction tank 12, seed crystals may exist in advance in the crystallization reaction tank 12, or seeds may be present in the crystallization reaction tank 12 in advance. Crystals may not be present. In order to perform a stable treatment, it is preferable that seed crystals exist in the crystallization reaction tank 12 in advance. The amount of seed crystals filled in the crystallization reaction tank 12 is not particularly limited as long as fluorine can be removed by a crystallization reaction. The concentration of fluorine in raw water, the concentration of slaked lime slurry, and the crystallization It is set as appropriate according to the operating conditions of the reactor 1.

  The seed crystal may be any material as long as it can precipitate a hardly soluble salt crystal formed on the surface thereof, and any material can be selected. For example, filtered sand, activated carbon, zircon sand, garnet sand, Particles composed of oxides of metal elements including random (trade name, manufactured by Nihon Cartrit Co., Ltd.), and particles composed of hardly soluble salts that are precipitates by crystallization reaction However, it is not limited to these. From the viewpoint that a purer hardly soluble salt can be obtained as a pellet or the like, particles (for example, fluorite in the case of calcium fluoride) including a hardly soluble salt that is a precipitate by a crystallization reaction are preferable. The shape and particle size of the seed crystal are appropriately set according to the flow rate in the crystallization reaction tank 12, the concentrations of fluorine and slaked lime, and are not particularly limited.

  In the case where the crystallization reaction tank 12 is filled with seed crystals in advance, for example, slaked lime is added to the raw water in the crystallization reaction tank 12, and the hardly soluble salt is precipitated on the seed crystals in the crystallization reaction tank 12. Pellets are formed to produce treated water with reduced fluorine. On the other hand, when seed crystals are not present in the crystallization reaction tank 12 in advance, the hardly soluble salt precipitated in the crystallization reaction tank 12 forms pellets by adding slaked lime to the raw water and grows. Will be. In any case, when the crystals in the crystallization reaction tank 12 grow to a certain extent, a drawing operation for drawing a part of the crystals from the crystallization reaction tank 12 and a seed crystal having a smaller particle diameter than the drawn crystals are newly added. A method is adopted in which crystals are continuously obtained by repeatedly performing a replenishment operation for replenishing.

  The crystallization reaction tank 12 may be a reaction tank that can react with fluorine and slaked lime in raw water to precipitate calcium fluoride crystals of a poorly soluble salt to produce treated water with reduced fluorine. The length, the inner diameter, the shape, and the like can be arbitrarily selected and are not particularly limited.

  As a crystallization reaction tank, as shown in FIG. 1, a stirring device 20 equipped with a stirring blade 22 and the like is installed in the crystallization reaction tank 12, and the inside of the crystallization reaction tank 12 is stirred by the stirring device 20 to flow pellets. And a stirring type crystallization reaction tank. The stirring blade 22 may be anything as long as the contents can be stirred in the crystallization reaction tank 12, and the installation mode of the stirring blade, the size of the stirring blade, and the like are not particularly limited.

  In addition, as the stirring type crystallization reaction tank 12, an inner peripheral wall is disposed so as to face the peripheral wall of the crystallization reaction tank 12, and a space between the inner and outer peripheral walls is used as a treated water discharge path. It may have a separation zone that improves the separation ability and prevents the insoluble salt particles from flowing out into the treated water. In this aspect, an aspect in which the treated water discharge pipe 34 is connected to the upper part of the treated water discharge path is preferable. In addition, in this treated water discharge path, a buffer plate made up of a plurality of baffle plates and a buffer plate made up of a plurality of rectifying plates at the inlet of the treated water discharge path in order to improve the separation performance of the pellets May be located. Details of this aspect are described in JP-A-2005-230735 and JP-A-2005-296888, and the crystallization reaction tank described in these patent documents can also be used in this embodiment.

  In order to measure the soluble fluorine concentration in the crystallization reaction tank 12 or in the treated water, a fluorine concentration measuring means such as a fluorine concentration meter may be installed in the crystallization reaction tank 12 or the treated water discharge pipe 34. Further, in order to measure the calcium concentration such as soluble calcium in the crystallization reaction tank 12 or in the treated water, a calcium concentration measuring means such as a calcium concentration meter is installed in the crystallization reaction tank 12 or the treated water discharge pipe 34. Also good. The installation position of the fluorine concentration meter, calcium concentration meter and the like in the crystallization reaction tank 12 is not particularly limited. For example, when measuring the concentration in the treated water, the vicinity of the exit of the crystallization reaction tank 12 Can be installed.

  The treated water in which fluorine generated by the crystallization reaction is reduced in the crystallization reaction tank 12 is discharged to the outside of the crystallization reaction tank 12. The treated water can be discharged from any part according to the liquid flow in the crystallization reaction tank 12. In FIG. 1, the treated water discharged from the upper part of the crystallization reaction tank 12 is finally discharged out of the system through the treated water discharge pipe 34. You may install a treated water storage tank in the back | latter stage of the crystallization reaction tank 12. FIG.

  In the obtained treated water, for example, the fluorine concentration is usually about 500 mg-F / L or less as total fluorine including insoluble fluorine such as calcium fluoride, and usually about 50 mg-F / L or less as soluble fluorine ions. The calcium concentration is pH 2-3, and is usually about 50 mg-Ca / L as soluble calcium ions, but is not limited thereto.

  The treated water obtained by treating the raw water may be further treated in a precipitation tank. In the sedimentation tank, for example, calcium fluoride is generated by adjusting the pH to 3 to 12, preferably 4 to 11, and the treated water with further reduced fluorine concentration is obtained by precipitation and removal of fluorine. Can do.

  By precipitating calcium fluoride crystals of a hardly soluble salt in the crystallization reaction tank 12 by the crystallization reaction apparatus and the crystallization reaction method according to the present embodiment, the fluorine in the raw water is recovered as the hardly soluble salt crystals. As a result, treated water with reduced fluorine is produced. In the present embodiment, the fluorine recovery rate (1- (fluorine content in treated water / fluorine content in raw water)) is preferably 80% or more, more preferably 85% or more, and even more preferably 90% or more. Can be achieved.

FIG. 5 is a schematic configuration diagram illustrating another example of the crystallization reaction apparatus according to the reference example . In the crystallization reaction apparatus 7 shown in FIG. 5, the same code | symbol is attached | subjected about the structure similar to the crystallization reaction apparatus 1 shown in FIG. As shown in FIG. 5, the crystallization reaction device 7 includes a raw water storage tank 10, a calcium agent storage tank 11, and a crystallization reaction tank 12.

  In the crystallization reaction apparatus 7 of FIG. 5, a raw water addition pipe 32 from the raw water storage tank 10 is connected to the crystallization reaction tank 12 via a pump 18 which is a raw water addition means, and a calcium from the calcium agent storage tank 11 is connected. The agent addition pipe 29 is connected via a pump 15 which is a calcium agent addition means, and a pH adjuster addition pipe 38 is connected. Moreover, the acid addition piping 30a, 30b is connected to the raw | natural water storage tank 10 and the calcium-agent storage tank 11 via the pumps 16a, 16b which are acid addition means. In addition, since acid should just be supplied to the fluorine-containing raw water and calcium agent before being supplied to the crystallization reaction tank 12 through the acid addition pipes 30a and 30b from the pumps 16a and 16b, the acid addition pipes 30a and 30b are It is not necessarily connected to the raw water storage tank 10 and the calcium agent storage tank 11, and may be connected to the raw water addition pipe 32 and the calcium agent addition pipe 29.

  The crystallization reaction tank 12 is provided with an inner peripheral wall facing the peripheral wall of the crystallization reaction tank 12. A treated water discharge path 40 is formed between the peripheral wall and the inner peripheral wall, and the treated water discharge pipe 34 is connected to the treated water discharge path 40. As described above, the treated water discharge passage 40 is provided to improve the separation ability between the calcium fluoride crystals and the treated water and prevent the calcium fluoride crystals from flowing out into the treated water. However, it is not always necessary. A crystallization discharge pipe 42 is connected to the bottom of the crystallization reaction tank 12, and calcium fluoride crystals generated by the crystallization reaction are discharged from the crystallization discharge pipe 42. Further, a draft tube 26 and a pH meter 24 as pH measuring means are installed in the crystallization reaction tank 12, and in the draft tube 26, stirring for stirring the motor and the fluid in the crystallization reaction tank 12. A stirrer 20 that is a stirring means including blades 22 is installed.

  Next, the operation of the crystallization reaction method and the crystallization reaction apparatus according to this embodiment will be described.

  The acid is supplied to the raw water storage tank 10 and the calcium agent storage tank 11 through the acid addition pipes 30a and 30b by the pumps 16a and 16b (acid addition process). Next, the fluorine-containing raw water to which the acid has been added is added from the raw water storage tank 10 to the crystallization reaction tank 12 through the raw water addition pipe 32 by the pump 18. Further, the calcium agent to which the acid has been added is added from the calcium agent storage tank 11 to the crystallization reaction tank 12 through the calcium agent addition pipe 29 by the pump 15. Then, in the crystallization reaction tank 12, while the fluorine-containing raw water and the calcium agent are stirred by the stirring device 20, the fluorine contained in the raw water reacts with the calcium agent to produce calcium fluoride crystals ( Crystallization reaction step). The calcium fluoride crystals generated by the crystallization reaction are discharged from the crystallization discharge pipe 42. The treated water in which fluorine has been reduced by the crystallization reaction passes through the treated water discharge passage 40 and is discharged from the treated water discharge pipe 34 to the outside of the crystallization reaction tank 12.

  In this embodiment, an acid is added to the fluorine-containing raw water and calcium agent before being supplied to the crystallization reaction tank 12 to lower the pH of the fluorine-containing raw water and calcium agent. Here, as described above, some fluorine-containing raw water contains ammonia, and among them, there is buffered hydrofluoric acid containing ammonia in a high concentration. The pH of this buffered hydrofluoric acid (raw water) is often 4-7. In addition, there is also fluorine-containing raw water in which caustic soda or the like is added in order to recover ammonia in buffered hydrofluoric acid and a strong alkaline state having a pH of 12 or higher is obtained. Thus, when the pH of the fluorine-containing raw water before being supplied to the crystallization reaction tank 12 is 4 or more, the acid is added so that the pH of the raw water is less than 4, preferably less than 2. However, even when the fluorine-containing raw water is a weak acid (pH 2.7 to 3.0) such as hydrofluoric acid, that is, even when the pH of the fluorine-containing raw water is less than 4 before being supplied to the crystallization reaction tank 12. When an acid is added so as to lower the pH of the fluorine-containing raw water, the fluorine recovery rate can be improved, and a more effective effect can be obtained.

  The calcium agent used for the crystallization reaction is generally calcium chloride having a pH of about 5 to 7, slaked lime slurry having a pH of 12 or more, and most of them have a pH of 4 or more. When the calcium agent used for the precipitation reaction (calcium agent before being supplied to the crystallization reaction tank 12) is pH 4 or more, an acid is added so that the pH is less than 4, preferably less than 2, and the crystal Even when the pH of the calcium agent used in the precipitation reaction is less than 4, an acid is added so that the pH of the calcium agent is lowered.

  Thus, after acid is added to the fluorine-containing raw water and calcium agent before being supplied to the crystallization reaction tank 12 and the pH is lowered (if the pH of the raw water and calcium agent is 4 or more, the pH is reduced). Rather than supplying the acid, fluorine-containing raw water and calcium agent separately to the crystallization reaction tank 12 by supplying the fluorine-containing raw water and calcium agent added with acid to the crystallization reaction tank 12, The solubility of calcium fluoride becomes high, and the production of fine calcium fluoride due to the rapid reaction between the calcium agent and fluorine can be reduced. As a result, it becomes possible to stably form calcium fluoride crystals having a large particle size by the crystallization reaction, and the amount of fine calcium fluoride mixed into the treated water can be extremely reduced. The recovery rate of fluorine can be greatly improved.

  In this embodiment, an acid is added to at least one of the fluorine-containing raw water and the calcium agent before being supplied to the crystallization reaction tank 12, and the pH of at least one of the fluorine-containing raw water and the calcium agent is lowered. However, it is preferable to set the pH of both the fluorine-containing raw water and the calcium agent to less than 4, and it is more preferable to lower the pH of the fluorine-containing raw water as much as possible.

  When the acid is added to the fluorine-containing raw water, the raw water is preferably added to the crystallization reaction tank 12 in the vicinity of the stirring blade 22. When an acid is added to the calcium agent, the calcium agent is preferably added to the crystallization reaction tank 12 in the vicinity of the stirring blade 22. Furthermore, when an acid is added to both the fluorine-containing raw water and the calcium agent, the raw water and the calcium agent are preferably added to the crystallization reaction tank 12 in the vicinity of the stirring blade 22. Thus, the fluorine-containing raw water to which the acid is added and the calcium agent are added in the vicinity of the stirring blade 22 and quickly diffused in the crystallization reaction tank 12, thereby suppressing a rapid reaction between the calcium agent and fluorine. Production of calcium fluoride can be reduced.

FIG. 6 is a schematic configuration diagram illustrating another example of the crystallization reaction apparatus according to the reference example . In the crystallization reaction apparatus 8 shown in FIG. 6, the pH meter 24 and the pump 16b are electrically connected, and the pH of the crystallization reaction tank 12 measured by the pH meter 24 (that is, the crystallization reaction tank 12). The amount of acid added to the calcium agent may be controlled by controlling the pump 16b based on the pH of the reaction solution.

FIG. 7 is a schematic configuration diagram illustrating another example of the crystallization reaction apparatus according to the reference example . In the crystallization reaction apparatus 9 shown in FIG. 7, the pH meter 24 and the pump 16a are electrically connected, and the pH of the crystallization reaction tank 12 measured by the pH meter 24 (that is, the crystallization reaction tank 12). The amount of acid added to the fluorine-containing raw water may be controlled by controlling the pump 16a based on the pH of the reaction solution.

  Here, the amount of acid added to the fluorine-containing raw water and the calcium agent so that the pH of the crystallization reaction tank 12 is preferably in the range of 0.8 to 3, more preferably in the range of 1 to 2.3. To control. If the pH of the crystallization reaction solution in the crystallization reaction tank 12 is less than 0.8, the proportion of fluorine in the raw water that does not become calcium fluoride increases, and a large amount of soluble fluorine exists in the treated water. As a result, the fluorine recovery rate may decrease, and if the pH exceeds 3, a large amount of fine calcium fluoride may be generated due to a rapid reaction between calcium fluoride and fluorine.

  The pH of the crystallization reaction tank 12 is adjusted by controlling the amount of acid added to the fluorine-containing raw water and the calcium agent and controlling the amount of the pH adjuster supplied from the pH adjuster addition pipe 38. May be performed.

  The crystallization reaction apparatus described in FIGS. 5 to 7 adds an acid to at least one of the fluorine-containing raw water and the calcium agent before being supplied to the crystallization reaction tank 12, and includes the raw water and the calcium agent. It is intended to lower at least one of the pH values, and if it does not exceed the gist, any technique and condition, for example, the technique and condition of the crystallization reaction apparatus described in FIGS. Can be adopted.

  Hereinafter, although an example and a comparative example are given and the present invention is explained more concretely in detail, the present invention is not limited to the following examples.

( Examples 1-2, Reference Examples 1-2 )
Experiments were performed under the following conditions by changing the slaked lime and acid addition positions and the pH conditions of the crystallization reaction tank, and the fluorine concentrations of the treated water were compared. The experimental results are shown in Table 1. In Examples 1 and 2, the injection points of the slaked lime addition pipe and the acid addition pipe were set near the stirring blade of the crystallization reaction tank as shown in FIG. It was installed at a position of 120 mm in the radial direction from the rotation center (the distance from the rotation center of the stirring blade is 1.6 times the rotation radius). The pH of the crystallization reaction solution in the crystallization reaction tank was controlled to 2.5 ± 0.2 in Example 1 and 1.5 ± 0.2 in Example 2. In Reference Example 1 , the injection point of the slaked lime addition pipe was the same as in Examples 1 and 2, and the acid was added to the slaked lime addition pipe as shown in FIG. In Reference Example 2 , the injection point of the slaked lime addition pipe was the same as in Examples 1 and 2, and acid was added to the raw water storage tank as shown in FIG.

  The used draft tube had a diameter of 250 mm, and was installed so that the upper end was located 150 mm from the water surface and the lower end was located 150 mm below the stirring blade. The treated water fluorine concentration referred to here is the total fluorine concentration including SS-type fluorine (= calcium fluoride) and soluble fluorine.

<Experimental conditions>
Crystallization reaction tank capacity: 150 L (500 mmφ × 1200 mmH)
Fluorine concentration of raw water containing fluorine: 10000 mg / L
Fluorine-containing raw water flow rate: 50 L / hr
Slaked lime slurry concentration: 10% by weight
Acid: hydrochloric acid (5% by weight)
Stirring blade diameter: 200mm

(Comparative Examples 1-3)
In Comparative Example 1, without adding acid, the injection point of the slaked lime addition pipe was set near the water surface of the crystallization reaction tank ((rotated from the center of rotation of the stirring blade at a position 50 mm below the water surface of the crystallization reaction tank). In the comparative example 2, the injection point of the slaked lime-added piping was used without adding the acid in the example of 220 mm in the radial direction (the distance from the rotation center of the stirring blade was 6.4 times the rotation radius). It was added in the same manner as in Example 1. In Comparative Example 3, the injection point of the slaked lime addition pipe was added in the same manner as in Comparative Example 1, and the injection point of the acid addition pipe was added in the same manner as in Example 1. Otherwise, the operation was performed. The experiment was performed under the same conditions as in Example 1. The fluorine concentrations of the treated water were compared, and the pH was not adjusted in Comparative Examples 1 and 2. The experimental results are shown in Table 1.

Thus, in Examples 1 and 2 and Reference Examples 1 and 2 , while adding an acid and stirring with a stirring blade, slaked lime is added to the raw water in the vicinity of the stirring blade to generate calcium fluoride crystals. As a result, the fluorine concentration of the treated water could be reduced. In particular, the results of Example 2 were good. Compared with the conventional method of using calcium chloride as a calcium agent and the method of dissolving slaked lime in acid to form calcium chloride and then injecting it into the crystallization reaction tank, the amount of acid and alkali used is reduced and the cost required for the treatment Reduced.

( Reference examples 3 and 4 )
In Reference Example 3 , the crystallization reaction apparatus shown in FIG. 5 was used, an acid was added to the fluorine-containing raw water before being added to the crystallization reaction tank, the experiment was conducted by changing the pH of the fluorine-containing raw water, and treated water. The fluorine concentration of was measured. In Reference Example 3 , the pH of calcium chloride (calcium agent) before being added to the crystallization reaction tank was controlled to be 7.0 or 1.5. In Reference Example 4 , an experiment was performed by changing the pH of calcium chloride by adding an acid to calcium chloride before being added to the crystallization reaction tank using the crystallization reaction apparatus shown in FIG. Concentration was measured. In Reference Example 4 , the pH of the raw fluorine-containing water before being added to the crystallization reaction tank was controlled to 7.0, 2.7, or 1.5. Other experimental conditions in Reference Examples 3 and 4 are shown below.

<Experimental conditions>
Crystallization reaction tank capacity: 150 L (500 mmφ × 1200 mmH)
Fluorine concentration of raw water containing fluorine: 10000 mg / L
Fluorine-containing raw water flow rate: 30L / hr
Calcium chloride concentration: 10% by weight
Acid: hydrochloric acid (35% by weight)
Crystallization reactor pH: 2.0 to 2.3

FIG. 8 is a diagram showing the relationship between the pH of fluorine-containing raw water and the fluorine concentration of treated water in Reference Example 3 , and FIG. 9 shows the relationship between the pH of calcium chloride and the fluorine concentration of treated water in Reference Example 4 . FIG. As can be seen from FIG. 8, in Reference Example 3 , the fluorine concentration of the treated water can be reduced by adding acid to the fluorine-containing raw water before being added to the crystallization reaction tank to make the pH less than 4. It was. Further, as can be seen from FIG. 9, in Reference Example 4 , the fluorine concentration of the treated water can be reduced by adding an acid to calcium chloride before being added to the crystallization reaction tank to make the pH less than 4. did it. In particular, rather than adding acid to calcium chloride (calcium agent) before adding to the crystallization reaction tank to make the pH less than 4, add acid to the fluorine-containing raw water before adding to the crystallization reaction tank to adjust the pH to 4. It has been found that the effect of reducing the fluorine concentration of the treated water is greater when the ratio is less than 1.

It is a schematic block diagram which shows an example of the crystallization reaction apparatus which concerns on embodiment of this invention. It is a schematic block diagram which shows an example of the crystallization reaction tank in the crystallization reaction apparatus which concerns on embodiment of this invention. It is a schematic block diagram which shows the other example of the crystallization reaction apparatus which concerns on a reference example . It is a schematic block diagram which shows the other example of the crystallization reaction apparatus which concerns on a reference example . It is a schematic block diagram which shows the other example of the crystallization reaction apparatus which concerns on a reference example . It is a schematic block diagram which shows the other example of the crystallization reaction apparatus which concerns on a reference example . It is a schematic block diagram which shows the other example of the crystallization reaction apparatus which concerns on a reference example . It is a figure which shows the relationship between the pH of the fluorine-containing raw | natural water in the reference example 3, and the fluorine concentration of treated water. It is a figure which shows the relationship between pH of the calcium chloride in the reference example 4, and the fluorine concentration of a treated water. It is a schematic block diagram which shows an example of the conventional fluidized bed type crystallization reaction apparatus. It is a schematic block diagram which shows an example of the conventional stirring type crystallization reaction apparatus.

Explanation of symbols

  1, 7, 8, 9 Crystallization reactor, 10 Raw water storage tank, 11 Calcium agent storage tank, 12 Crystallization reaction tank, 14, 15, 16, 16a, 16b, 18 Pump, 20 Stirrer, 22 Stirring blade, 24, 36 pH meter, 26 Draft tube, 28 Slaked lime addition pipe, 29 Calcium agent addition pipe, 30, 30a, 30b Acid addition pipe, 32 Raw water addition pipe, 34 Treated water discharge pipe, 38 pH adjuster added pipe, 40 Treated water discharge Road, 42 Crystallization discharge pipe.

Claims (4)

A crystallization reaction apparatus for generating calcium fluoride crystals by adding slaked lime to raw water containing fluorine,
A crystallization reaction tank comprising a stirring means having a stirring blade, and adding the slaked lime to the raw water to generate calcium fluoride crystals;
Slaked lime addition means for adding the slaked lime in the vicinity of the stirring blade;
An acid addition means for adding an acid ,
The crystallization reaction apparatus , wherein the acid addition means injects the acid into the vicinity of the stirring blade . The crystallization reaction apparatus according to claim 1 ,
The crystallization reaction apparatus, wherein the crystallization reaction tank has a pH in the range of 0.8 to 3. A crystallization reaction method for generating calcium fluoride crystals by adding slaked lime to raw water containing fluorine,
While stirring with a stirring blade, a crystallization reaction step of generating calcium fluoride crystals by adding the slaked lime to the raw water in the vicinity of the stirring blade;
An acid addition step of adding an acid ,
In the acid addition step, the acid is injected in the vicinity of the stirring blade . A crystallization reaction method according to claim 3 ,
PH in the said crystallization reaction process is the range of 0.8-3, The crystallization reaction method characterized by the above-mentioned.

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